Age-related skull fracture patterns in infants after low-height falls.

Background: Prior research and experience has increased physician understanding of infant skull fracture prediction. However, patterns related to fracture length, nonlinearity, and features of complexity remain poorly understood, and differences across infant age groups have not been previously explored.

Methods: To determine how infant and low-height fall characteristics influence fracture patterns, we collected data from 231 head CT 3D reconstructions and quantified length and nonlinearity using a custom image processing code.

Correlation of collagen fibril properties and inner limiting membrane thickness with vitreoretinal adhesion in human eyes.

Vitreoretinal adhesive strength is thought to play a mechanical role in various retinal diseases; however, collagen fibril properties and inner limiting membrane (ILM) thickness have not been quantitatively correlated to adhesive strength. In this work, we quantified the relationship between collagen fibril density, angle, length, and ILM thickness with vitreoretinal adhesive strength to advance our understanding of structure-function relationships in vitreoretinal adhesion. Following mechanical peel tests, human retinal sections from the equator and posterior pole of donors 42-89 years of age were extracted and processed for transmission electron microscopy.

Mechanical characterization of the human pia-arachnoid complex.

Traumatic brain injury (TBI) is a significant problem in global health that affects a wide variety of patients. Mild forms of TBI, commonly referred to as concussion, are a result of rapid accelerations of the head from either direct or indirect impacts. Kinetic energy from the impact is transferred into deformation of the brain, leading to cellular disruption.

Spatial distribution of human arachnoid trabeculae.

Traumatic brain injury (TBI) is a common injury modality affecting a diverse patient population. Axonal injury occurs when the brain experiences excessive deformation as a result of head impact. Previous studies have shown that the arachnoid trabeculae (AT) in the subarachnoid space significantly influence the magnitude and distribution of brain deformation during impact.